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An investigation into the effects of band gap and doping concentration on Cu(InGa)Se2 solar cell efficiency

机译：带隙和掺杂浓度对Cu（InGa）Se2太阳能电池效率的影响研究

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摘要

A simulation study of a Cu(In1 − xGax)Se2 (CIGS) thin film solar cell has been carried out with maximum efficiency of 24.27 % (Voc = 0.856 V, Jsc = 33.09 mA/cm² and FF = 85.73 %). This optimized efficiency is obtained by determining the optimum band gap of the absorber and varying the doping concentration of constituent layers. The Ga content denoted by x = Ga/(In + Ga) is selected as 0.35 which provides the optimum band gap of absorber layer as 1.21 eV. Theoretically, the effects of Ga fraction “x” on CIGS absorber band gap are investigated and to avoid the lattice mismatch effect, the efficiency measurements due to the CIGS band gaps >1.21 eV have not come to the consideration. A one-dimensional simulator ADEPT/F 2.1 has been used to analyze the fabricated device parameters and hence to calculate open circuit voltage, short circuit current, fill factor and efficiency.

机译：已对Cu（In1-xGax）Se2（CIGS）薄膜太阳能电池进行了模拟研究，最大效率为24.27％（Voc = 0.856V，Jsc = 33.09mA / cm ^{2 和FF = 85.73％）。通过确定吸收体的最佳带隙并改变组成层的掺杂浓度，可以获得最佳效率。选择由x = Ga /（In + Ga）表示的Ga含量为0.35，这可将吸收层的最佳带隙设为1.21 eV。从理论上讲，研究了Ga分数“ x”对CIGS吸收带隙的影响，为避免晶格失配效应，未考虑CIGS带隙> 1.21eV引起的效率测量。一维仿真器ADEPT / F 2.1已用于分析制造的设备参数，从而计算开路电压，短路电流，填充系数和效率。}

著录项

期刊名称 SpringerPlus
作者
Md. Asaduzzaman; Mehedi Hasan; Ali Newaz Bahar;
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作者单位

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年(卷),期 -1(5),-1
年度 -1
页码 578
总页数 8
原文格式 PDF
正文语种
中图分类
关键词
CIGS thin film Absorber band gap Doping concentration Lattice mismatch Efficiency;

机译：CIGS薄膜;吸收带隙;掺杂浓度;晶格失配;效率;

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专利

1. First-principles study on the alkali chalcogenide secondary compounds in Cu（In,Ga）Se2 and Cu2ZnSn（S,Se）4 thin film solar cells [J] . Xian Zhang, Dan Han, Shiyou Chen, 能源化学：英文版 . 2018,第004期
2. A simulation approach for investigating the performances of cadmium telluride solar cells using doping concentrations, carrier lifetimes, thickness of layers, and band gaps [J] . Shah Deb Kumar, Devendra K. C., Muddassir M., Solar Energy . 2021,第Mara期

机译：一种使用掺杂浓度，载流子寿命，层，层和带空隙来研究碲化镉太阳能电池性能的模拟方法
3. Improvement of band gap profile in Cu(InGa)Se_2 solar cells through rapid thermal annealing [J] . D.S. Chen, J. Yang, Z.B. Yang, Materials Research Bulletin . 2014,第juna期

机译：通过快速热退火改善Cu（InGa）Se_2太阳能电池的带隙分布
4. Influence of the donor doping density in CdS and Zn(O,S) buffer layers on the external quantum efficiency of Cu(In,Ga)Se2 thin film solar cell [J] . Alain Kassine EHEMBA, Moustapha DIENG, Demba DIALLO, International Journal of Engineering Trends and Technology . 2015,第6期

机译：CdS和Zn（O，S）缓冲层中施主掺杂密度对Cu（In，Ga）Se2薄膜太阳能电池外部量子效率的影响
5. An Estimate of Maximal Conversion Efficiency in Regard to Doping Concentrations and Junction Position in Cu(In,Ga)Se2 Solar Cells [C] . Yamada, A., Matsubara, . 2006

机译：关于Cu（In，Ga）Se2太阳能电池中掺杂浓度和结位置的最大转换效率的估算
6. Comparative analysis of Cu(InGa)Se2 solar cells. [D] . Counts, Kahl. 2016

机译：Cu（InGa）Se2太阳能电池的比较分析。
7. Employing Si solar cell technology to increase efficiency of ultra-thin Cu(InGa)Se2 solar cells [O] . Bart Vermang, Jörn Timo Wätjen, Viktor Fjällström, -1

机译：利用硅太阳能电池技术提高超薄Cu（InGa）Se2太阳能电池的效率
8. An investigation into the effects of band gap and doping concentration on Cu(In,Ga)Se solar cell efficiency [O] . 2016

机译：带隙和掺杂浓度对Cu（In，Ga）Se太阳能电池效率的影响研究

An investigation into the effects of band gap and doping concentration on Cu(InGa)Se2 solar cell efficiency

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